CN102071463A - Rare earth-doped germanium-gallate RExLn1-xGaGe2O7 luminescent material and melt crystal growth method thereof - Google Patents
Rare earth-doped germanium-gallate RExLn1-xGaGe2O7 luminescent material and melt crystal growth method thereof Download PDFInfo
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- CN102071463A CN102071463A CN 201110003278 CN201110003278A CN102071463A CN 102071463 A CN102071463 A CN 102071463A CN 201110003278 CN201110003278 CN 201110003278 CN 201110003278 A CN201110003278 A CN 201110003278A CN 102071463 A CN102071463 A CN 102071463A
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Abstract
The invention discloses a rare earth (RE)-doped (RE is Pr, Sm, Eu, Tb, Dy, Er, Ho, Tm, Yb, Cr, Ti and Bi) LnGaGe2O7 (Ln is La and Gd) luminescent material and a melt crystal growth method thereof. The percentage concentration of the doped atoms is 0.01-50%. Raw materials prepared in a certain proportion are subjected to full mixing, suppress forming and high-temperature sintering and then become starting raw materials for growing crystal; the starting growth raw materials are put in a crucible for heating and full smelting, and then become starting melt grown by a melt method; and then growth is carried out by using melt methods such as a pulling method, a Bridgman method, a temperature gradient technique and the like. The luminescent material in the invention can be used for the fields of display, illumination, solid state laser technologies and the like.
Description
Technical field
The present invention relates to luminescent material and field of crystal growth, be specifically related to rare earth element Pr, Sm, Eu, Tb, Dy, Er, Ho, Tm, Yb and non-rare earth Cr, Ti, the adulterated RE of Bi
xLn
1-xGaGe
2O
7Luminescent material, and their crystal growth method by melt method.
Technical background
Development new pattern laser material is the important foundation that promotes the Solid State Laser technical progress, and luminescent material has important and application widely in the demonstration field.Rare earth germanium gallate is as the following advantage of having of laserable material: the ion that is replaced in (1) doping active ions and the matrix all is a rare earth ion, and replacing easily mixes enters single luminescence center and can realize big doped in concentrations profiled even full the doping; (2) fusing point of rare earth germanium gallate is lower, favourable crystal pulling method single crystal growing.A.A.Kaminsk
[1]Synthesized serial rare-earth germanium gallate (LnGaGe Deng the people
2O
7, Ln=La, Pr, Nd, Sm, Eu, Gd, Tb, Dy, spacer No.14, P 2
1/ c), and use Czochralski grown LaGaGe
2O
7And GdGaGe
2O
7Monocrystalline, and studied Nd
3+Adulterated LnGaGe
2O
7(Ln=La, spectrum property Gd).The present invention is mainly with LaGaGe
2O
7, GdGaGe
2O
7Be matrix, mix Pr, Sm, Eu, Tb, Dy, Er, Ho, Tm, Yb, Cr, Ti, Bi therein as active ions, obtain luminescent material, they are expected to become novel laserable material.
Summary of the invention
The purpose of this invention is to provide rare earth doped germanium gallate RE
xLn
1-xGaGe
2O
7Luminescent material and crystal growth method by melt method thereof, the present invention is mainly with LaGaGe
2O
7, GdGaGe
2O
7Be matrix, mix Pr, Sm, Eu, Tb, Dy, Er, Ho, Tm, Yb, Cr, Ti, Bi therein as active ions, obtain luminescent material, the luminescent material that obtained performance is good can be used in demonstration, illumination and the Solid State Laser.
Technology of the present invention and embodiment are as follows:
Rare earth doped germanium gallate RE
xLn
1-xGaGe
2O
7Luminescent material is characterized in that: the compound molecule formula can be expressed as RE
xLn
1-xGaGe
2O
7, RE represents rare earth element Pr, Sm, Eu, Tb, Dy, Er, Ho, Tm, Yb, and non-rare earth Cr, Ti, Bi, and Ln represents rare-earth elements La, Gd, and the span of x is: 0.0001≤x≤0.5.
Described rare earth doped germanium gallate RE
xLn
1-xGaGe
2O
7The crystal growth method by melt method of luminescent material is characterized in that: may further comprise the steps:
(1) when RE is not Tb, adopts RE
2O
3, Ln
20
3, Ga
2O
3, GeO
2As raw material, prepare burden by following chemical combination formula, after the thorough mixing of will preparing burden was even, solid state reaction at high temperature took place, obtain the required polycrystal raw material of growing crystal:
(2) when RE is Tb, adopt Tb
4O
7, Ln
2O
3, Ga
2O
3, GeO
2As raw material, prepare burden by following chemical combination formula, will prepare burden thorough mixing evenly after, the required polycrystal raw material of growing crystal at high temperature takes place to obtain after the solid state reaction:
(3) have segregation effect of insulated grid oxidation in the crystal growth method by melt, the crystalline component and the food ingredient that grow have difference, but the dosage of each component is within the indicated scope of described compound molecule formula;
(4) compacting of raw material and sintering obtain the crystal growth initial feed: need suppress and sintering press forming to confected materials in (1)-(2); Sintering temperature is between 750-1700 ℃, and sintering time is 10-72 hour; Perhaps the raw material behind the press forming directly is used as the growing crystal raw material without extra sintering;
(5) the crystal growth initial feed is put into growth crucible,, obtain the crystal growth initial melt by heating and fully fusing; Adopting crystal growth method by melt technology then---crystal pulling method, falling crucible method, warm terraced method or heat exchange growing method are grown.
Described rare earth doped germanium gallate RE
xLn
1-xGaGe
2O
7Crystal growth method by melt method, it is characterized in that: do not adopt the seed crystal oriented growth, perhaps adopt the seed crystal oriented growth; For adopting the seed crystal oriented growth, seed crystal is RE
xLn
1-xGaGe
2O
7Monocrystalline or LnGaGe
2O
7Monocrystalline, seed crystal direction are crystalline [100], [010] or [001] direction, and other any direction.
Described rare earth doped germanium gallate RE
xLn
1-xGaGe
2O
7The crystal growth method by melt method of luminescent material is characterized in that: in the described batching, and raw materials used Tb
4O
7, RE
2O
3, Ln
2O
3, Ga
2O
3, GeO
2, can adopt other compound of corresponding Tb, RE, Ln, Ga, Ge to replace, the raw material synthetic method comprises high temperature solid state reaction, synthetic, the gas-phase synthesizing method of liquid phase, can finally form compound R E by chemical reaction but need to satisfy
xLn
1-xGaGe
2O
7This-condition.
Described rare earth doped germanium gallate RE
xLn
1-xGaGe
2O
7The crystal growth method by melt method of luminescent material is characterized in that: owing to have a component effect of segregation in the crystal growing process, establish described RE
xLn
1-xGaGe
2O
7The segregation coefficient of certain element is k in the crystal, and k=0.01-1 then when the quality of the compound of this element in the chemical combination formula of Tb, RE, Ln, Ga, Ge in the step of described (1)-(2) is W, then should be adjusted into W/k in batching.
Beneficial effect of the present invention: the luminescent material that the present invention obtains has high stopping power, high luminous efficiency and fast decay, can be used in demonstration, illumination and the Solid State Laser.
Embodiment
Rare earth doped germanium gallate RE
xLn
1-xGaGe
2O
7Luminescent material, its compound molecule formula can be expressed as RE
xLn
1-xGaGe
2O
7, RE represents rare earth element Pr, Sm, Eu, Tb, Dy, Er, Ho, Tm, Yb, and non-rare earth Cr, Ti, Bi, and Ln represents rare-earth elements La, Gd, and the span of x is: 0.0001≤x≤0.5.
Rare earth doped germanium gallate RE
xLn
1-xGaGe
2O
7The crystal growth method by melt method of luminescent material may further comprise the steps:
(1) when RE is not Tb, adopts RE
2O
3, Ln
2O
3, Ga
2O
3, GeO
2As raw material, prepare burden by following chemical combination formula, after the thorough mixing of will preparing burden was even, solid state reaction at high temperature took place, obtain the required polycrystal raw material of growing crystal:
(2) when RE is Tb, adopt Tb
4O
7, Ln
2O
3, Ga
2O
3, GeO
2As raw material, prepare burden by following chemical combination formula, will prepare burden thorough mixing evenly after, the required polycrystal raw material of growing crystal at high temperature takes place to obtain after the solid state reaction:
(3) have segregation effect of insulated grid oxidation in the crystal growth method by melt, the crystalline component and the food ingredient that grow have difference, but the dosage of each component is within the indicated scope of described compound molecule formula;
(4) compacting of raw material and sintering obtain the crystal growth initial feed: need suppress and sintering press forming to confected materials in (1)-(2); Sintering temperature is between 750-1700 ℃, and sintering time is 10-72 hour; Perhaps the raw material behind the press forming directly is used as the growing crystal raw material without extra sintering;
(5) the crystal growth initial feed is put the people and grow in the crucible,, obtain the crystal growth initial melt by heating and fully fusing; Adopting crystal growth method by melt technology then---crystal pulling method, falling crucible method, warm terraced method or heat exchange growing method are grown.
Described rare earth doped germanium gallate RE
xLn
1-xGaGe
2O
7Crystal growth method by melt method, do not adopt the seed crystal oriented growth, perhaps adopt the seed crystal oriented growth; For adopting the seed crystal oriented growth, seed crystal is RE
xLn
1-xGaGe
2O
7Monocrystalline or LnGaGe
2O
7Monocrystalline, seed crystal direction are crystalline [100], [010] or [001] direction, and other any direction.
Described rare earth doped germanium gallate RE
xLn
1-xGaGe
2O
7The crystal growth method by melt method of luminescent material, in the described batching, raw materials used Tb
4O
7, RE
2O
3, Ln
2O
3, Ga
2O
3, GeO
2, can adopt other compound of corresponding Tb, RE, Ln, Ga, Ge to replace, the raw material synthetic method comprises high temperature solid state reaction, synthetic, the gas-phase synthesizing method of liquid phase, can finally form compound R E by chemical reaction but need to satisfy
xLn
1-xGaGe
2O
7This condition.
Described rare earth doped germanium gallate RE
xLn
1-xGaGe
2O
7The crystal growth method by melt method of luminescent material owing to have a component effect of segregation in the crystal growing process, is established described RE
xLn
1-xGaGe
2O
7The segregation coefficient of certain element is k in the crystal, and k=0.01-1 then when the quality of the compound of this element in the chemical combination formula of Tb, RE, Ln, Ga, Ge in the step of described (1)-(2) is W, then should be adjusted into W/k in batching.
Claims (5)
1. rare earth doped germanium gallate RE
xLn
1-xGaGe
2O
7Luminescent material is characterized in that: the compound molecule formula can be expressed as RE
xLn
1-xGaGe
2O
7, RE represents rare earth element Pr, Sm, Eu, Tb, Dy, Er, Ho, Tm, Yb, and non-rare earth Cr, Ti, Bi, and Ln represents rare-earth elements La, Gd, and the span of x is: 0.0001≤x≤0.5.
2. rare earth doped germanium gallate RE as claimed in claim 1
xLn
1-xGaGe
2O
7The crystal growth method by melt method of luminescent material is characterized in that: may further comprise the steps:
(1) when RE is not Tb, adopts RE
2O
3, Ln
2O
3, Ga
2O
3, GeO
2As raw material, prepare burden by following chemical combination formula, after the thorough mixing of will preparing burden was even, solid state reaction at high temperature took place, obtain the required polycrystal raw material of growing crystal:
(2) when RE is Tb, adopt Tb
4O
7, Ln
2O
3, Ga
2O
3, GeO
2As raw material, prepare burden by following chemical combination formula, will prepare burden thorough mixing evenly after, the required polycrystal raw material of growing crystal at high temperature takes place to obtain after the solid state reaction:
(3) have segregation effect of insulated grid oxidation in the crystal growth method by melt, the crystalline component and the food ingredient that grow have difference, but the dosage of each component is within the indicated scope of described compound molecule formula;
(4) compacting of raw material and sintering obtain the crystal growth initial feed: need suppress and sintering press forming to confected materials in (1)-(2); Sintering temperature is between 750-1700 ℃, and sintering time is 10-72 hour; Perhaps the raw material behind the press forming directly is used as the growing crystal raw material without extra sintering;
(5) the crystal growth initial feed is put the people and grow in the crucible,, obtain the crystal growth initial melt by heating and fully fusing; Adopting crystal growth method by melt technology then---crystal pulling method, falling crucible method, warm terraced method or heat exchange growing method are grown.
3. rare earth doped germanium gallate RE as claimed in claim 2
xLn
1-xGaGe
2O
7Crystal growth method by melt method, it is characterized in that: do not adopt the seed crystal oriented growth, perhaps adopt the seed crystal oriented growth; For adopting the seed crystal oriented growth, seed crystal is RE
xLn
1-xGaGe
2O
7Monocrystalline or LnGaGe
2O
7Monocrystalline, seed crystal direction are crystalline [100], [010] or [001] direction, and other any direction.
4. rare earth doped germanium gallate RE as claimed in claim 2
xLn
1-xGaGe
2O
7The crystal growth method by melt method of luminescent material is characterized in that: in the described batching, and raw materials used Tb
4O
7, RE
2O
3, Ln
2O
3, Ga
2O
3, GeO
2, can adopt other compound of corresponding Tb, RE, Ln, Ga, Ge to replace, the raw material synthetic method comprises high temperature solid state reaction, synthetic, the gas-phase synthesizing method of liquid phase, can finally form compound R E by chemical reaction but need to satisfy
xLn
1-xGaGe
2O
7This condition.
5. rare earth doped germanium gallate RE as claimed in claim 2
xLn
1-xGaGe
2O
7The crystal growth method by melt method of luminescent material is characterized in that: owing to have a component effect of segregation in the crystal growing process, establish described RE
xLn
1-xGaGe
2O
7The segregation coefficient of certain element is k in the crystal, and k=0.01-1 then when the quality of the compound of this element in the chemical combination formula of Tb, RE, Ln, Ga, Ge in the step of described (1)-(2) is W, then should be adjusted into W/k in batching.
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|---|---|---|---|
| CN2011100032780A CN102071463B (en) | 2011-01-08 | 2011-01-08 | Rare earth-doped germanium-gallate RExLn1-xGaGe2O7 luminescent material and melt crystal growth method thereof |
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| CN2011100032780A CN102071463B (en) | 2011-01-08 | 2011-01-08 | Rare earth-doped germanium-gallate RExLn1-xGaGe2O7 luminescent material and melt crystal growth method thereof |
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Cited By (4)
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|---|---|---|---|---|
| CN103146384A (en) * | 2013-01-17 | 2013-06-12 | 昆明理工大学 | Bismuth and europium co-doped germinate white light fluorescent powder and preparation method |
| CN108301046A (en) * | 2018-03-14 | 2018-07-20 | 江苏海林电子新材料科技有限公司 | A kind of optical crystal and its growing method of the preparation of large scale doped gallium lanthanum crystal |
| CN109868138A (en) * | 2017-12-05 | 2019-06-11 | 亿光电子工业股份有限公司 | Opto-electronic device |
| CN111455465A (en) * | 2019-01-18 | 2020-07-28 | 美国西门子医疗系统股份有限公司 | Crystal growth atmosphere for producing oxyorthosilicate materials |
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| CN102071463B (en) | 2012-10-31 |
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